[][src]Trait futures_util::stream::StreamExt

pub trait StreamExt: Stream {
    fn next(&mut self) -> Next<Self>
    where
        Self: Unpin
, { ... }
fn into_future(self) -> StreamFuture<Self>
    where
        Self: Sized + Unpin
, { ... }
fn map<T, F>(self, f: F) -> Map<Self, F>
    where
        F: FnMut(Self::Item) -> T,
        Self: Sized
, { ... }
fn enumerate(self) -> Enumerate<Self>
    where
        Self: Sized
, { ... }
fn filter<Fut, F>(self, f: F) -> Filter<Self, Fut, F>
    where
        F: FnMut(&Self::Item) -> Fut,
        Fut: Future<Output = bool>,
        Self: Sized
, { ... }
fn filter_map<Fut, T, F>(self, f: F) -> FilterMap<Self, Fut, F>
    where
        F: FnMut(Self::Item) -> Fut,
        Fut: Future<Output = Option<T>>,
        Self: Sized
, { ... }
fn then<Fut, F>(self, f: F) -> Then<Self, Fut, F>
    where
        F: FnMut(Self::Item) -> Fut,
        Fut: Future,
        Self: Sized
, { ... }
fn collect<C: Default + Extend<Self::Item>>(self) -> Collect<Self, C>
    where
        Self: Sized
, { ... }
fn concat(self) -> Concat<Self>
    where
        Self: Sized,
        Self::Item: Extend<<Self::Item as IntoIterator>::Item> + IntoIterator + Default
, { ... }
fn fold<T, Fut, F>(self, init: T, f: F) -> Fold<Self, Fut, T, F>
    where
        F: FnMut(T, Self::Item) -> Fut,
        Fut: Future<Output = T>,
        Self: Sized
, { ... }
fn flatten(self) -> Flatten<Self>
    where
        Self::Item: Stream,
        Self: Sized
, { ... }
fn skip_while<Fut, F>(self, f: F) -> SkipWhile<Self, Fut, F>
    where
        F: FnMut(&Self::Item) -> Fut,
        Fut: Future<Output = bool>,
        Self: Sized
, { ... }
fn take_while<Fut, F>(self, f: F) -> TakeWhile<Self, Fut, F>
    where
        F: FnMut(&Self::Item) -> Fut,
        Fut: Future<Output = bool>,
        Self: Sized
, { ... }
fn for_each<Fut, F>(self, f: F) -> ForEach<Self, Fut, F>
    where
        F: FnMut(Self::Item) -> Fut,
        Fut: Future<Output = ()>,
        Self: Sized
, { ... }
fn take(self, n: usize) -> Take<Self>
    where
        Self: Sized
, { ... }
fn skip(self, n: usize) -> Skip<Self>
    where
        Self: Sized
, { ... }
fn fuse(self) -> Fuse<Self>
    where
        Self: Sized
, { ... }
fn by_ref(&mut self) -> &mut Self { ... }
fn zip<St>(self, other: St) -> Zip<Self, St>
    where
        St: Stream,
        Self: Sized
, { ... }
fn chain<St>(self, other: St) -> Chain<Self, St>
    where
        St: Stream<Item = Self::Item>,
        Self: Sized
, { ... }
fn peekable(self) -> Peekable<Self>
    where
        Self: Sized
, { ... }
fn forward<S>(self, sink: S) -> Forward<Self, S>
    where
        S: Sink<Self::Ok>,
        Self: TryStream<Error = S::Error> + Sized
, { ... }
fn inspect<F>(self, f: F) -> Inspect<Self, F>
    where
        F: FnMut(&Self::Item),
        Self: Sized
, { ... }
fn left_stream<B>(self) -> Either<Self, B>
    where
        B: Stream<Item = Self::Item>,
        Self: Sized
, { ... }
fn right_stream<B>(self) -> Either<B, Self>
    where
        B: Stream<Item = Self::Item>,
        Self: Sized
, { ... }
fn poll_next_unpin(&mut self, cx: &mut Context) -> Poll<Option<Self::Item>>
    where
        Self: Unpin
, { ... }
fn select_next_some(&mut self) -> SelectNextSome<Self>
    where
        Self: Unpin + FusedStream
, { ... } }

An extension trait for Streams that provides a variety of convenient combinator functions.

Provided methods

Important traits for Next<'_, St>
fn next(&mut self) -> Next<Self> where
    Self: Unpin

Creates a future that resolves to the next item in the stream.

Note that because next doesn't take ownership over the stream, the Stream type must be Unpin. If you want to use next with a !Unpin stream, you'll first have to pin the stream. This can be done by boxing the stream using [Box::pin] or pinning it to the stack using the pin_mut! macro from the pin_utils crate.

Examples

use futures::stream::{self, StreamExt};

let mut stream = stream::iter(1..=3);

assert_eq!(stream.next().await, Some(1));
assert_eq!(stream.next().await, Some(2));
assert_eq!(stream.next().await, Some(3));
assert_eq!(stream.next().await, None);

Important traits for StreamFuture<St>
fn into_future(self) -> StreamFuture<Self> where
    Self: Sized + Unpin

Converts this stream into a future of (next_item, tail_of_stream). If the stream terminates, then the next item is None.

The returned future can be used to compose streams and futures together by placing everything into the "world of futures".

Note that because into_future moves the stream, the Stream type must be Unpin. If you want to use into_future with a !Unpin stream, you'll first have to pin the stream. This can be done by boxing the stream using [Box::pin] or pinning it to the stack using the pin_mut! macro from the pin_utils crate.

Examples

use futures::stream::{self, StreamExt};

let stream = stream::iter(1..=3);

let (item, stream) = stream.into_future().await;
assert_eq!(Some(1), item);

let (item, stream) = stream.into_future().await;
assert_eq!(Some(2), item);

fn map<T, F>(self, f: F) -> Map<Self, F> where
    F: FnMut(Self::Item) -> T,
    Self: Sized

Maps this stream's items to a different type, returning a new stream of the resulting type.

The provided closure is executed over all elements of this stream as they are made available. It is executed inline with calls to poll_next.

Note that this function consumes the stream passed into it and returns a wrapped version of it, similar to the existing map methods in the standard library.

Examples

use futures::stream::{self, StreamExt};

let stream = stream::iter(1..=3);
let stream = stream.map(|x| x + 3);

assert_eq!(vec![4, 5, 6], stream.collect::<Vec<_>>().await);

fn enumerate(self) -> Enumerate<Self> where
    Self: Sized

Creates a stream which gives the current iteration count as well as the next value.

The stream returned yields pairs (i, val), where i is the current index of iteration and val is the value returned by the stream.

enumerate() keeps its count as a usize. If you want to count by a different sized integer, the zip function provides similar functionality.

Overflow Behavior

The method does no guarding against overflows, so enumerating more than usize::max_value() elements either produces the wrong result or panics. If debug assertions are enabled, a panic is guaranteed.

Panics

The returned stream might panic if the to-be-returned index would overflow a usize.

Examples

use futures::stream::{self, StreamExt};

let stream = stream::iter(vec!['a', 'b', 'c']);

let mut stream = stream.enumerate();

assert_eq!(stream.next().await, Some((0, 'a')));
assert_eq!(stream.next().await, Some((1, 'b')));
assert_eq!(stream.next().await, Some((2, 'c')));
assert_eq!(stream.next().await, None);

fn filter<Fut, F>(self, f: F) -> Filter<Self, Fut, F> where
    F: FnMut(&Self::Item) -> Fut,
    Fut: Future<Output = bool>,
    Self: Sized

Filters the values produced by this stream according to the provided asynchronous predicate.

As values of this stream are made available, the provided predicate f will be run against them. If the predicate returns a Future which resolves to true, then the stream will yield the value, but if the predicate returns a Future which resolves to false, then the value will be discarded and the next value will be produced.

Note that this function consumes the stream passed into it and returns a wrapped version of it, similar to the existing filter methods in the standard library.

Examples

use futures::future;
use futures::stream::{self, StreamExt};

let stream = stream::iter(1..=10);
let evens = stream.filter(|x| future::ready(x % 2 == 0));

assert_eq!(vec![2, 4, 6, 8, 10], evens.collect::<Vec<_>>().await);

fn filter_map<Fut, T, F>(self, f: F) -> FilterMap<Self, Fut, F> where
    F: FnMut(Self::Item) -> Fut,
    Fut: Future<Output = Option<T>>,
    Self: Sized

Filters the values produced by this stream while simultaneously mapping them to a different type according to the provided asynchronous closure.

As values of this stream are made available, the provided function will be run on them. If the future returned by the predicate f resolves to Some(item) then the stream will yield the value item, but if it resolves to None then the next value will be produced.

Note that this function consumes the stream passed into it and returns a wrapped version of it, similar to the existing filter_map methods in the standard library.

Examples

use futures::stream::{self, StreamExt};

let stream = stream::iter(1..=10);
let evens = stream.filter_map(|x| async move {
    if x % 2 == 0 { Some(x + 1) } else { None }
});

assert_eq!(vec![3, 5, 7, 9, 11], evens.collect::<Vec<_>>().await);

fn then<Fut, F>(self, f: F) -> Then<Self, Fut, F> where
    F: FnMut(Self::Item) -> Fut,
    Fut: Future,
    Self: Sized

Computes from this stream's items new items of a different type using an asynchronous closure.

The provided closure f will be called with an Item once a value is ready, it returns a future which will then be run to completion to produce the next value on this stream.

Note that this function consumes the stream passed into it and returns a wrapped version of it.

Examples

use futures::stream::{self, StreamExt};

let stream = stream::iter(1..=3);
let stream = stream.then(|x| async move { x + 3 });

assert_eq!(vec![4, 5, 6], stream.collect::<Vec<_>>().await);

Important traits for Collect<St, C>
fn collect<C: Default + Extend<Self::Item>>(self) -> Collect<Self, C> where
    Self: Sized

Transforms a stream into a collection, returning a future representing the result of that computation.

The returned future will be resolved when the stream terminates.

Examples

use futures::channel::mpsc;
use futures::stream::StreamExt;
use std::thread;

let (tx, rx) = mpsc::unbounded();

thread::spawn(move || {
    for i in 1..=5 {
        tx.unbounded_send(i).unwrap();
    }
});

let output = rx.collect::<Vec<i32>>().await;
assert_eq!(output, vec![1, 2, 3, 4, 5]);

Important traits for Concat<St>
fn concat(self) -> Concat<Self> where
    Self: Sized,
    Self::Item: Extend<<Self::Item as IntoIterator>::Item> + IntoIterator + Default

Concatenate all items of a stream into a single extendable destination, returning a future representing the end result.

This combinator will extend the first item with the contents of all the subsequent results of the stream. If the stream is empty, the default value will be returned.

Works with all collections that implement the Extend trait.

Examples

use futures::channel::mpsc;
use futures::stream::StreamExt;
use std::thread;

let (tx, rx) = mpsc::unbounded();

thread::spawn(move || {
    for i in (0..3).rev() {
        let n = i * 3;
        tx.unbounded_send(vec![n + 1, n + 2, n + 3]).unwrap();
    }
});

let result = rx.concat().await;

assert_eq!(result, vec![7, 8, 9, 4, 5, 6, 1, 2, 3]);

Important traits for Fold<St, Fut, T, F>
fn fold<T, Fut, F>(self, init: T, f: F) -> Fold<Self, Fut, T, F> where
    F: FnMut(T, Self::Item) -> Fut,
    Fut: Future<Output = T>,
    Self: Sized

Execute an accumulating asynchronous computation over a stream, collecting all the values into one final result.

This combinator will accumulate all values returned by this stream according to the closure provided. The initial state is also provided to this method and then is returned again by each execution of the closure. Once the entire stream has been exhausted the returned future will resolve to this value.

Examples

use futures::stream::{self, StreamExt};

let number_stream = stream::iter(0..6);
let sum = number_stream.fold(0, |acc, x| async move { acc + x });
assert_eq!(sum.await, 15);

fn flatten(self) -> Flatten<Self> where
    Self::Item: Stream,
    Self: Sized

Flattens a stream of streams into just one continuous stream.

Examples

use futures::channel::mpsc;
use futures::stream::StreamExt;
use std::thread;

let (tx1, rx1) = mpsc::unbounded();
let (tx2, rx2) = mpsc::unbounded();
let (tx3, rx3) = mpsc::unbounded();

thread::spawn(move || {
    tx1.unbounded_send(1).unwrap();
    tx1.unbounded_send(2).unwrap();
});
thread::spawn(move || {
    tx2.unbounded_send(3).unwrap();
    tx2.unbounded_send(4).unwrap();
});
thread::spawn(move || {
    tx3.unbounded_send(rx1).unwrap();
    tx3.unbounded_send(rx2).unwrap();
});

let output = rx3.flatten().collect::<Vec<i32>>().await;
assert_eq!(output, vec![1, 2, 3, 4]);

fn skip_while<Fut, F>(self, f: F) -> SkipWhile<Self, Fut, F> where
    F: FnMut(&Self::Item) -> Fut,
    Fut: Future<Output = bool>,
    Self: Sized

Skip elements on this stream while the provided asynchronous predicate resolves to true.

This function, like Iterator::skip_while, will skip elements on the stream until the predicate f resolves to false. Once one element returns false all future elements will be returned from the underlying stream.

Examples

use futures::future;
use futures::stream::{self, StreamExt};

let stream = stream::iter(1..=10);

let stream = stream.skip_while(|x| future::ready(*x <= 5));

assert_eq!(vec![6, 7, 8, 9, 10], stream.collect::<Vec<_>>().await);

fn take_while<Fut, F>(self, f: F) -> TakeWhile<Self, Fut, F> where
    F: FnMut(&Self::Item) -> Fut,
    Fut: Future<Output = bool>,
    Self: Sized

Take elements from this stream while the provided asynchronous predicate resolves to true.

This function, like Iterator::take_while, will take elements from the stream until the predicate f resolves to false. Once one element returns false it will always return that the stream is done.

Examples

use futures::future;
use futures::stream::{self, StreamExt};

let stream = stream::iter(1..=10);

let stream = stream.take_while(|x| future::ready(*x <= 5));

assert_eq!(vec![1, 2, 3, 4, 5], stream.collect::<Vec<_>>().await);

Important traits for ForEach<St, Fut, F>
fn for_each<Fut, F>(self, f: F) -> ForEach<Self, Fut, F> where
    F: FnMut(Self::Item) -> Fut,
    Fut: Future<Output = ()>,
    Self: Sized

Runs this stream to completion, executing the provided asynchronous closure for each element on the stream.

The closure provided will be called for each item this stream produces, yielding a future. That future will then be executed to completion before moving on to the next item.

The returned value is a Future where the Output type is (); it is executed entirely for its side effects.

To process each item in the stream and produce another stream instead of a single future, use then instead.

Examples

use futures::future;
use futures::stream::{self, StreamExt};

let mut x = 0;

{
    let fut = stream::repeat(1).take(3).for_each(|item| {
        x += item;
        future::ready(())
    });
    fut.await;
}

assert_eq!(x, 3);

fn take(self, n: usize) -> Take<Self> where
    Self: Sized

Creates a new stream of at most n items of the underlying stream.

Once n items have been yielded from this stream then it will always return that the stream is done.

Examples

use futures::stream::{self, StreamExt};

let stream = stream::iter(1..=10).take(3);

assert_eq!(vec![1, 2, 3], stream.collect::<Vec<_>>().await);

fn skip(self, n: usize) -> Skip<Self> where
    Self: Sized

Creates a new stream which skips n items of the underlying stream.

Once n items have been skipped from this stream then it will always return the remaining items on this stream.

Examples

use futures::stream::{self, StreamExt};

let stream = stream::iter(1..=10).skip(5);

assert_eq!(vec![6, 7, 8, 9, 10], stream.collect::<Vec<_>>().await);

fn fuse(self) -> Fuse<Self> where
    Self: Sized

Fuse a stream such that poll_next will never again be called once it has finished. This method can be used to turn any Stream into a FusedStream.

Normally, once a stream has returned None from poll_next any further calls could exhibit bad behavior such as block forever, panic, never return, etc. If it is known that poll_next may be called after stream has already finished, then this method can be used to ensure that it has defined semantics.

The poll_next method of a fused stream is guaranteed to return None after the underlying stream has finished.

Examples

use futures::executor::block_on_stream;
use futures::stream::{self, StreamExt};
use futures::task::Poll;

let mut x = 0;
let stream = stream::poll_fn(|_| {
    x += 1;
    match x {
        0..=2 => Poll::Ready(Some(x)),
        3 => Poll::Ready(None),
        _ => panic!("should not happen")
    }
}).fuse();

let mut iter = block_on_stream(stream);
assert_eq!(Some(1), iter.next());
assert_eq!(Some(2), iter.next());
assert_eq!(None, iter.next());
assert_eq!(None, iter.next());
// ...

fn by_ref(&mut self) -> &mut Self

Borrows a stream, rather than consuming it.

This is useful to allow applying stream adaptors while still retaining ownership of the original stream.

Examples

use futures::stream::{self, StreamExt};

let mut stream = stream::iter(1..5);

let sum = stream.by_ref()
                .take(2)
                .fold(0, |a, b| async move { a + b })
                .await;
assert_eq!(sum, 3);

// You can use the stream again
let sum = stream.take(2)
                .fold(0, |a, b| async move { a + b })
                .await;
assert_eq!(sum, 7);

fn zip<St>(self, other: St) -> Zip<Self, St> where
    St: Stream,
    Self: Sized

An adapter for zipping two streams together.

The zipped stream waits for both streams to produce an item, and then returns that pair. If either stream ends then the zipped stream will also end.

Examples

use futures::stream::{self, StreamExt};

let stream1 = stream::iter(1..=3);
let stream2 = stream::iter(5..=10);

let vec = stream1.zip(stream2)
                 .collect::<Vec<_>>()
                 .await;
assert_eq!(vec![(1, 5), (2, 6), (3, 7)], vec);

fn chain<St>(self, other: St) -> Chain<Self, St> where
    St: Stream<Item = Self::Item>,
    Self: Sized

Adapter for chaining two streams.

The resulting stream emits elements from the first stream, and when first stream reaches the end, emits the elements from the second stream.

use futures::stream::{self, StreamExt};

let stream1 = stream::iter(vec![Ok(10), Err(false)]);
let stream2 = stream::iter(vec![Err(true), Ok(20)]);

let stream = stream1.chain(stream2);

let result: Vec<_> = stream.collect().await;
assert_eq!(result, vec![
    Ok(10),
    Err(false),
    Err(true),
    Ok(20),
]);

fn peekable(self) -> Peekable<Self> where
    Self: Sized

Creates a new stream which exposes a peek method.

Calling peek returns a reference to the next item in the stream.

Important traits for Forward<St, Si>
fn forward<S>(self, sink: S) -> Forward<Self, S> where
    S: Sink<Self::Ok>,
    Self: TryStream<Error = S::Error> + Sized

A future that completes after the given stream has been fully processed into the sink and the sink has been flushed and closed.

This future will drive the stream to keep producing items until it is exhausted, sending each item to the sink. It will complete once the stream is exhausted, the sink has received and flushed all items, and the sink is closed. Note that neither the original stream nor provided sink will be output by this future. Pass the sink by Pin<&mut S> (for example, via forward(&mut sink) inside an async fn/block) in order to preserve access to the Sink.

fn inspect<F>(self, f: F) -> Inspect<Self, F> where
    F: FnMut(&Self::Item),
    Self: Sized

Do something with each item of this stream, afterwards passing it on.

This is similar to the Iterator::inspect method in the standard library where it allows easily inspecting each value as it passes through the stream, for example to debug what's going on.

Important traits for Either<A, B>
fn left_stream<B>(self) -> Either<Self, B> where
    B: Stream<Item = Self::Item>,
    Self: Sized

Wrap this stream in an Either stream, making it the left-hand variant of that Either.

This can be used in combination with the right_stream method to write if statements that evaluate to different streams in different branches.

Important traits for Either<A, B>
fn right_stream<B>(self) -> Either<B, Self> where
    B: Stream<Item = Self::Item>,
    Self: Sized

Wrap this stream in an Either stream, making it the right-hand variant of that Either.

This can be used in combination with the left_stream method to write if statements that evaluate to different streams in different branches.

fn poll_next_unpin(&mut self, cx: &mut Context) -> Poll<Option<Self::Item>> where
    Self: Unpin

A convenience method for calling Stream::poll_next on Unpin stream types.

Important traits for SelectNextSome<'_, St>
fn select_next_some(&mut self) -> SelectNextSome<Self> where
    Self: Unpin + FusedStream

Returns a Future that resolves when the next item in this stream is ready.

This is similar to the next method, but it won't resolve to None if used on an empty Stream. Instead, the returned future type will return true from FusedFuture::is_terminated when the Stream is empty, allowing select_next_some to be easily used with the [select!] macro.

If the future is polled after this Stream is empty it will panic. Using the future with a FusedFuture-aware primitive like the [select!] macro will prevent this.

Examples

use futures::{future, select};
use futures::stream::{StreamExt, FuturesUnordered};

let mut fut = future::ready(1);
let mut async_tasks = FuturesUnordered::new();
let mut total = 0;
loop {
    select! {
        num = fut => {
            // First, the `ready` future completes.
            total += num;
            // Then we spawn a new task onto `async_tasks`,
            async_tasks.push(async { 5 });
        },
        // On the next iteration of the loop, the task we spawned
        // completes.
        num = async_tasks.select_next_some() => {
            total += num;
        }
        // Finally, both the `ready` future and `async_tasks` have
        // finished, so we enter the `complete` branch.
        complete => break,
    }
}
assert_eq!(total, 6);
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Implementors

impl<T: ?Sized> StreamExt for T where
    T: Stream
[src]

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